SU815102A1 - Mounting joint of post with girder-panel structure of ferroconcrete unsplit bridge - Google Patents

Description

The invention relates to mechanical engineering and can be used in the construction of reinforced concrete frame-continuous bridges and overpasses. _

Known mounting joint of the ^T-5 The samples GOVERNMENTAL racks raft construction concrete girder frame-beam axle comprising ^ inserts placed between the beams and the transverse prestressed reinforcement constricting nozzle racks, bearings and end portions of adjacent plate-beams of the beam structure, which contact surface coated with adhesive [1]. fifteen

A disadvantage of the known mounting joint is that it does not work reliably under temporary loads due to the occurrence of significant shear stresses on the contact surfaces of the liners, nozzles and end sections of the beams and possible loss of prestress during the bridge operation. *5

Closest to the proposed technical essence is the mounting joint of the rack with the slab-beam construction of the reinforced concrete ramified bridge, including 30 releases of the working reinforcement of the rack and interconnected by welding outlets of the upper working reinforcement of adjacent beams of the plate-beam structure adjacent to the rack, monolithic concrete [[2].

The disadvantage of this mounting joint is the insufficiently high crack resistance of the bridge support sections at the operational stage.

The purpose of the present invention is to increase the crack resistance of the support section of the bridge.

The goal is achieved by the fact that the mounting joint of the rack with the slab-beam structure of the reinforced concrete ramified bridge, including the releases of the working reinforcement and the racks and connected by welding the releases of the upper working fittings of adjacent beams of the slab-beam structure adjacent to the rack, the monolithic concrete, the mounting joint is equipped with an installed on the end of the rack and reinforced with stiffeners from above with a metal sheet having openings for the outlets of the working reinforcement of the rack, and the outlets of the working reinforcement ki welded to the stiffeners.

In FIG. 1 shows a frame-continuous bridge;, in FIG. 2 - mounting joint, rc ^ horizontal section; in FIG. 3 - the same, longitudinal section.

The mounting joint of 1 rack 2 with a slab-beam construction 3 of iron _ (concrete frame-continuous bridge ⁵ includes releases of working reinforcement 4 racks 2, monolithic together with the outlets of the upper working reinforcement 5 connected adjacent to each other by welding beams adjacent to both sides of the rack 6 of a slab-beam structure 3 and a metal sheet 8 supported on the end of the rack 2, reinforced from above by stiffening ribs 7, having openings for the outlet 15 of the working reinforcement 4 racks, which are welded to the stiffening ribs 7. To the metal This sheet 8 can be welded segments rebars 9. 20

Introduction to the design of the mounting joint of the distribution element, made in the form of a metal sheet 8 reinforced with stiffening ribs, allows you to distribute the pressure 25 from the rack to a large area of the slab-beam structure 3, which, in turn, leads to> increased strength and crack resistance of the support sections of the frame-uncut bridge proportionally the ratio of the metal sheet to the cross-sectional area of the rack.

The beams 6, made in the form of prefabricated elements, are mounted using temporary supports (not shown in the drawing) and beams are supported on them at the level of the metal sheet 8, after which the outlets of the upper working reinforcement of 5 adjacent beams are welded and the assembly joint is monolithic.

Claims (2)

(54) MOUNTING JOINT OF A RACK WITH A PLATED-BENCHED CONSTRUCTION OF A REINFORCED CONCRETE-NERL-CUTTING BRIDGE In FIG. 1 shows a frame-continuous bridge;, FIG. 2 - assembly joint, g 2 horizontal section; in fig. 3 - the same, longitudinal section. Mounting joint 1 of a rack 2 with a slab-beam construction 3 iron (a concrete frame-continuous bridge includes releases of working reinforcement 4 racks 2, homogeneous together with interconnected by welding releases of the upper working reinforcement 5 adjacent beams 6 slabno -gail structure 3 and a metal sheet 8 mounted on the end of a rack 2 and supported by the superstructure ribs 7 of stiffness, having openings for working fixtures 4 racks that are welded to the stiffening ribs 7. For sheet 8, lengths of reinforcing bars 9 can be welded. Introduction to the construction of a junction of a distribution element made in the form of a metal sheet 8 reinforced by stiffeners allows the pressure from the stand to be distributed over a large TILTING PLATE 3 SITE, which leads in turn to an increase in strength and the crack resistance of the support sections of the frame-insoluble bridge is proportional to the ratio of the metal sheet to the cross-sectional area of the stand. The installation of beams made in the form of prefabricated elements is carried out using temporary supports (not shown in the drawing) and with beams supported on them in the level of the metal sheet 8, after which the issues of the upper working reinforcement 5 of the adjacent beams are welded and the joint joint is monolithic. Formula of the invention: A mounting junction of a rack with a plate-and-beam construction of a reinforced concrete frame-cutting bridge, including the issues of the working reinforcement of the rack and interconnected by welding, the issues of the upper working reinforcement of adjacent slabs of the beam-beam construction, concrete monolithing, characterized in that with the aim of increasing the crack resistance of the bridge support section, the mounting joint is equipped with a metal sheet mounted on the end of the rack and reinforced from above with stiffeners STI issues under the working reinforcement strut, and the working reinforcement releases rack welded to pebpsuvi stiffness. Sources of information taken into account in the examination 1. USSR author's certificate in application No. 2700172 / 29-33, cl. E 01 D 7/02, 19.12,78. 2. Kryltsov EI, etc. Modern reinforced concrete bridges. M., Transport, 1974, p. 134-136, fig. III.7 (prototype).